Memoryless common-mode insensitive and low pulling vco

ABSTRACT

A voltage controlled oscillator (VCO) is disclosed. The VCO includes an active device. The VCO comprises an active device, wherein the active device further includes an n-type transistor having a drain, gate and bulk; a p-type transistor having a drain, gate and bulk. The n-type transistor and the p-type transistor share a common source. The active device further includes a first capacitor coupled between the gate of n-type transistor and the gate of p-type transistor; a second capacitor coupled between the drain of the n-type transistor and the drain of p-type transistor; and a third capacitor coupled between the bulk of n-type transistor and the bulk of p-type transistor. The VCO includes a tuning block coupled to the common source to form a common gate amplifier and at least one tuning element coupled to the active device for changing the overall capacitance of the VCO.

CROSS-REFERENCE TO RELATED APPLICATION

This application is a continuation-in-part of U.S. patent applicationSer. No. 14/745,261, filed ON Jun. 19, 2015, entitled “ACTIVE DEVICEWHICH HAS A HIGH BREAKDOWN VOLTAGE, IS MEMORY-LESS, TRAPS EVEN HARMONICSIGNALS AND CIRCUITS USED THEREWITH,” and claims benefit under 35 USC119(e) of U.S. Provisional Patent Application No. 62/100,397, filed onJan. 6, 2015, entitled “VERY LOW PHASE NOISE, MEMORYLESS COMMON-MODEINSENSITIVE, AND LOW PULLING VCO WITH CAPACITOR BANKS AS TUNING,” bothof which are incorporated herein by reference in their entirety.

FIELD OF THE INVENTION

The present invention relates generally to wireless devices and moreparticularly to voltage controlled oscillators utilized in such devices.

BACKGROUND

Wireless products are utilized in a variety of environments such asmobile (for example cellular and Wi-Fi for handsets) or non-mobile (forexample Wi-Fi for access points and routers). A voltage-controlledoscillator or VCO is an electronic oscillator whose oscillationfrequency is controlled by a voltage input. The applied input voltagedetermines the instantaneous oscillation frequency. Consequently,modulating signals applied to control input may cause frequencymodulation (FM) or phase modulation (PM). A VCO may also be part of aphase-locked loop. The VCO may be utilized in amplifiers in suchproducts to amplify the signals received or transmitted therefrom. Asthe market for wireless products develops there becomes an everincreasing need for more bandwidth and more data across mobile andnon-mobile networks with more demand for higher efficiency andlinearity. Therefore the communication of such data over these networksis becoming more and more difficult. For example, as the bandwidth goesup as network evolves, and at the same time the signals consolationsbecome more dense such as 802.11ax standard for WiFi application. As aresult, in-band and out of band noise of VCO becomes extremelyimportant. Also VCO pulling is a major issue. This case is more criticalin a presence of a high power amplifier for integration. In addition,traditional VCO architectures rely on a buffer to center output of coreVCO before driving the inverter chain following the core. This bufferconsumes major power and is another source of noise and disturbanceissue.

VCO tuning range is another issue. VCO tuning range is limited due tonoise of capacitor banks and its parasitics.

Devices and circuits in accordance with the present invention addresssuch a needs.

SUMMARY

A voltage controlled oscillator (VCO) and circuits utilized therewithare disclosed. In a first aspect, the VCO includes an active device. TheVCO comprises an active device, wherein the active device furtherincludes an n-type transistor having a drain, gate and bulk; a p-typetransistor having a drain, gate and bulk. The n-type transistor and thep-type transistor share a common source.

The active device further includes a first capacitor coupled between thegate of n-type transistor and the gate of p-type transistor; a secondcapacitor coupled between the drain of the n-type transistor and thedrain of p-type transistor; and a third capacitor coupled between thebulk of n-type transistor and the bulk of p-type transistor.

A differential voltage controlled oscillator (VCO) is also disclosed.The differential VCO includes first and second active devices. Each ofthe first and second active devices further includes an n typetransistor having a drain, gate and bulk. Each of the first and secondactive devices also includes a p-type transistor having a drain, gateand bulk. The n-type transistor and the p-type transistor share a commonsource. Each of the first and second active devices also includes afirst capacitor coupled between the gate of n-type transistor and thegate of p-type transistor. Each of the first and second active devicesalso includes a second capacitor coupled between the drain of the n-typetransistor and the drain of p-type transistor. Each of the first andsecond active devices further includes a third capacitor coupled betweenthe bulk of n-type transistor and the bulk of p-type transistor. Thedifferential VCO also includes a fourth capacitor coupled between thebulk of the n-type transistor of first active device to shared source ofsecond active device. The differential VCO also includes a fifthcapacitor coupled between bulk of p-type transistor of first activedevice to shard source of second active device. The differential VCOalso includes a sixth capacitor coupled between the bulk n-typetransistor of second active device to shared source of first activedevice. The differential VCO also includes a seventh capacitor coupledbetween the bulk of p-type transistor of second active device to sharedsource of first active device. The differential VCO also includes atuning block coupled to the common source to form a common gateamplifier. The differential VCO also includes at least one first tuningdevice coupled between the drain of the n-type transistor of the firstactive device and the drain of the n-type transistor of the secondactive device. The differential VCO also includes at least one secondtuning device coupled between the sources of the n-type and p-typetransistors of the first active device and the sources of the n-type andp-type transistors of the second active device. Finally, thedifferential VCO includes at least one third tuning device coupledbetween the drain of the p-type transistor of the first active deviceand the drain of the p-type transistor of the second first activedevice; wherein the differential VCO has a high breakdown voltage, ismemory less, very low close in and Ear phase noise, very low sensitivityto supply and ground disturbance and hence low pulling and traps evenharmonic signals.

The VCO includes a tuning block coupled to the common source to form acommon gate amplifier and at least one tuning element coupled to theactive device for changing the overall capacitance of the VCO. The VCOhas a high breakdown voltage, is memory less, very low close in and farphase noise, very low sensitivity to supply and ground disturbance andhence low pulling and traps even harmonic signals.

The VCO has a high breakdown voltage since each n-type and p-type devicesee a portion of total power supply voltage, is memory less since gatecapacitance coupled between -type and p-type gates and bulk capacitorscouping bulk of n-type and p-type trap common mode signals coupled tocritical node of devices and traps even harmonic signals. Thiscombination of n-type and p-type also distinguish between even and oddsignals that are generated during class AB or B or C, operation.

A system and method in accordance with the present invention provides anamplifier circuit that can be combined with a transformer to obtainincreased gain and positive feedback for voltage controlled oscillator(VCO) applications. The resulting device does not require a buffer ormemory since output signal can be taken off each common source which iscentered with respect to supply and therefore is smaller in size anduses less power than conventional VCOs.

BRIEF DESCRIPTION OF THE DRAWINGS

FIG. 1A is a schematic diagram of an active device utilized within avoltage controlled oscillator in accordance with the present invention.

FIG. 1B is a block diagram of the active device shown in FIG. 1 A.

FIG. 1C is a schematic diagram of a differential active device utilizedwithin a voltage controlled oscillator in accordance with the presentinvention.

FIG. 1D is a schematic diagram of a differential active device thatincludes capacitive tuning elements utilized within a voltage controlledoscillator in accordance with the present invention.

FIG. 1E is a block diagram of the differential active device shown inFIG. 1D.

FIG. 2A is a first embodiment of a tuning block in accordance with thepresent invention.

FIG. 2B is a second embodiment of a tuning block in accordance with thepresent invention.

FIG. 2C is a third embodiment of a tuning block in accordance withpresent invention

FIG. 3A is a block diagram of a common gate amplifier in accordance withthe present invention.

FIG. 3B is a block diagram of a combined common gate and common sourceamplifier in accordance with the present invention.

FIG. 4A is a block diagram of a first embodiment of a differentialcommon gate amplifier in accordance with the present invention.

FIG. 4B is a block diagram of a second embodiment of a differentialcommon gate amplifier in accordance with the present invention.

FIG. 4C is a block diagram of an embodiment of a differential combinedcommon gate and common source amplifier in accordance with the presentinvention.

FIG. 4D is a block diagram of an embodiment of a single ended voltagecontrolled oscillator (VCO) in accordance with the present invention.

FIG. 4E is a block diagram of an embodiment of a differential VCOarranged in the form of common-gate, common-source in accordance withthe present invention.

FIG. 4F is a block diagram of an embodiment of a cascaded VCO of CG-CSin accordance with the present invention.

FIG. 4G is a block diagram of an embodiment of a differential VCOarranged in the form of common-gate in accordance with the presentinvention.

FIG. 4H is a block diagram of an embodiment of a cascaded VCO of CG inaccordance with the present invention

FIG. 4I is a block diagram of an embodiment of a cascaded VCO of CG andCG-CS combination

FIG. 5 is a diagram of a two differential common gate active devicescoupled to coupled inductive differential tuning blocks in accordancewith the present invention.

FIG. 6 is a diagram of three common gate differential active devicescoupled to coupled inductive differential tuning blocks in accordancewith the present invention.

FIG. 7 is a diagram of four differential common Gate active devicescoupled to inductive differential tuning blocks in accordance with thepresent invention.

FIG. 8 is a diagram of showing where drain currents are added before theloop in a VCO in accordance with the present invention.

FIG. 9 is a diagram of showing where drain currents are added after theloop in a VCO in accordance with the present invention.

DETAILED DESCRIPTION

The present invention relates generally to wireless devices and moreparticularly to a voltage controlled oscillators utilized in suchdevices. The following description is presented to enable one ofordinary skill in the art to make and use the invention and is providedin the context of a patent application and its requirements. Variousmodifications to the preferred embodiments and the generic principlesand features described herein will be readily apparent to those skilledin the art. Thus, the 5476P 7 present invention is not intended to belimited to the embodiments shown, but is to be accorded the widest scopeconsistent with the principles and features described herein.

FIG. 1A is a schematic diagram of an active device 100 utilized within avoltage controlled oscillator in accordance with the present invention.The active device and its use within an amplifier circuit has beendescribed in detail in a copending U.S. application, owned by theassignee of the present application, entitled, ACTIVE DEVICE WHICH HAS AHIGH BREAKDOWN VOLTAGE, IS MEMORY-LESS, TRAPS EVEN HARMONIC SIGNALS ANDCIRCUITS USED THEREWITH, filed Jun. 19, 2015. The active device 100includes a n-type transistor 102 which includes a gate (gn), drain (dn)and bulk (bn) and a p-type transistor 104 which includes a gate (gp),drain (dp) and bulk (bp). The n-type transistor 102 and the p-typetransistor 104 share a common source (s). The active device 100 includesa first capacitor 106 coupled between gn and gp, a second capacitor 108coupled between dn and dp; and a third capacitor 110 coupled between bnand bp. The active device 100 has a high breakdown voltage due to thefour terminals (gate, drain bulk and source), is memory-less and trapseven harmonic signals when utilized with certain ampiiers such as ClassAB amplifiers.

FIG. 1B is a block diagram of the active device 100 shown in FIG. 1A.The n-type transistor 102 can be NPN bipolar or any other active elementfrom GaAs. The p-type transistor 104 can be PNP bipolar or any otheractive complementary from GaAs. The n-type transistor 102, can furtherbe protected by a cascode NMOS circuit. The p-type transistor 104 canfarther be protected by a cascode PMOS circuit. Capacitor 106 can be avariable capacitor, it can have a series resistor and or series inductorall being variable. Capacitor 106 can further be split into N number ofcapacitors with any series elements. Capacitor 108 can be a variablecapacitor, it can have a series resistor and or series inductor allbeing variable. Capacitor 108 can further be split into N number ofcapacitors with any series elements. Capacitor 110 can be a variablecapacitor, it can have a series resistor and or series inductor allbeing variable. Capacitor 110 can further be split into N number ofcapacitors with any series elements.

More capacitors can be coupled (parasitic or non-parasitic) from dn togn, dn to gp, dp to gp, dp to gn. These capacitors can be variable andor have series passive or active elements such as inductor, resistor,transformers and so on. Node gp can connect to a bias network. This biasnetwork can include any passive, such as resistor, capacitor, inductor,transformer and any combinations of them. The bias can also include anyactive elements.

In the case of using cascode transistor for both n-type and p-type oreither one, additional capacitors may be needed to connect drain ofcascode n-type to drain of cascode p-type similar to capacitor 110. Alsoa capacitor coupling a bulk of cascade n-type to a bulk of cascodep-type may be similar to capacitor 108. In addition, a capacitor can beconnected from gate of cascode n-type to the gate of cascade p-typesimilar to capacitor 106.

FIG. 1C is a schematic diagram of a differential active device 150utilized within a voltage controlled oscillator in accordance with thepresent invention. The differential active device 150 includes first andsecond active devices 100 coupled in a differential manner. Thedifferential active device includes capacitors 190 and 192 in bothactive devices 100 that are coupled from bulk to source of therespective transistors 102 and 104. The capacitors 190 and 192 improvethe linearity, stability, and self gain at high frequency of the commongate active device 150. Capacitor 106 which connects common gates ofn-type devices to common gates of p-type devices can trap any commonmode signals from supply, ground and self generated even harmonics (byVCO or amplifier entering class Aft B, C, . . . modes) such that toimprove issues related to VCO pulling and memory effects.

Capacitors 108 that connect bulk of n-type to bulk of p-type devicesprovide a path for any even harmonics generated by the class Aft B, C, .. . action of VCO or amplifier. Also providing filtering from supply orground noise to any bulk node, improving VCO pulling or issues relatedto memory effects.

FIG. 1D is a schematic diagram of a differential active device 151 thatincludes capacitive tuning elements 194 a, 194 b and 196 utilized withina voltage controlled oscillator in accordance with the presentinvention. The differential active device 151 includes similar to thatof FIG. 1C. Tuning elements 194 a and 194 b are coupled between thedrains of the active devices 100 to provide a coarse tuning adjustmentof the device 151. Tuning element 196 is coupled between the sources ofthe active devices 100 to provide a fine tuning adjustment of the device151. The tuning elements 194 a, 194 b and 196 are utilized to vary theeffective capacitance (including any parasitic capacitance that are notshown but obvious otherwise) of the device 151. This in turn can changethe center frequency of overall VCO structure. Tuning element 194 a canbe a variable capacitor, it can have a series resistor and or seriesinductor all being variable. Tuning element 194 a can further be splitinto N number of capacitors with any series elements. Tuning element 194b can be a variable capacitor, t can have a series resistor and orseries inductor all being variable. Tuning element 194 b can further besplit into N number of capacitors with any series elements. Capacitor110 can be a variable capacitor, it can have a series resistor and orseries inductor all being variable. Capacitor 110 can further be splitinto N number of capacitors with any series elements.

FIG. 1E is a block diagram of the differential active device shown inFIG. 1D. Similar to FIG. 1A, in each of the active devices, the n-typetransistor 102 can be NPN bipolar or any other active element from GaAs.The p-type transistor 104 can be PNP bipolar or any other activecomplementary from GaAs. The n-type transistor 102, can further beprotected by a cascode NMOS or NPN circuit. The p-type transistor 104can farther be protected by a cascode PMOS or PNP circuit. Capacitor 106can be a variable capacitor, it can have a series resistor and or seriesinductor all being variable. Capacitor 106 can further be split into Nnumber of capacitors with any series elements. Capacitor 108 can be avariable capacitor, it can have a series resistor and or series inductorall being variable. Capacitor 108 can further be split into N number ofcapacitors with any series elements. Capacitor 110 can be a variablecapacitor, it can have a series resistor and or series inductor allbeing variable. Capacitor 110 can further be split into N number ofcapacitors with any series elements.

More capacitors can be coupled (parasitic or non-parasitic) from dn togn, dn to gp, dp to gp, dp to gn. These capacitors can be variable andor have series passive or active elements such as inductor, resistor,transformers and so on. Node gp can connect to a bias network. This biasnetwork can include any passive, such as resistor, capacitor, inductor,transformer and any combinations of them. The bias can also include anyactive elements.

In the case of using cascode transistor for both n-type and p-type oreither one, additional capacitors may be needed to connect drain ofcascode n-type to drain of cascode p-type similar to capacitor 110. Alsoa capacitor coupling a bulk of cascade n-type to a bulk of cascodep-type may be similar to capacitor 108. In addition, a capacitor can beconnected from gate of cascode n-type to the gate of cascade p-typesimilar to capacitor 106.

If active device 100 in FIG. 1A or differential active devices 150 or151 of FIG. 1C and FIG. 1D respectively is driven in class AB or B or Cor D or any other class except class A, then the active device 151generates even and odd harmonic output currents flowing through dn anddp nodes. Active device 151 can distinguish between even and oddharmonics by generating similar direction current flow at nodes dn anddp in case of odd harmonics such as main signal or 3^(rd) harmonic.However active device 100 will generate opposing direction currents atnode dn and dp for even harmonic such as 2^(nd), 4^(th), 6^(th) and soon. Also a filtering action caused by capacitors 110, 108 and 106 willeffect magnitude of even harmonics flowing through dn and dp nodes.

FIG. 2A is a first embodiment of a tuning block 200 in accordance withthe present invention. The single ended tuning block 200 includes twoinputs dn and dp, one output, s and a voltage supply, (vdd) and ground,(gnd). Input signals in the form of current can be provided to nodes dnand dp, as I_in_n and I_in_p respectively. The tuning block 200 whichcan include a combination of all or few part of passive, inductors,capacitors, resistors and transformers but not limited to any has afunction of receiving I_in_n and I_in_p and providing an output current,I_s at node S with following condition: I_s>I_in_n+I_in_p. The tuningblock 200 is utilized to provide a linear output signal regardless ofthe power. A combination of tuning block 200 and the active device 100,form a common gate amplifier.

FIG. 3A is a block diagram of a single ended common gate amplifier inaccordance with the present invention. The common gate amplifiercomprises the active device 100 coupled to the tuning block 200. In thisembodiment, current I_s from the tuning block 200 is provided to thesource connection, S of the active device 100. Due to a common gateaction of device 100, the current I_s will split and a portion of it isdirected to dn as output current I_out_n and the other portion directedto dp as output current I_out_p. The gates gn and gp of the activedevice 100 are coupled to bias lines. (No signal is applied to gn andgp). Bulk nodes, bn and by are also coupled to their respective biaslines.

In the case when the active device 100 is operating under class Aft B,C, D and F mode, other even and odd harmonics current generate internalto the active device 100. These currents are directed toward dn and dp.For even harmonics such as AM (Amplitude modulated) currents and 2^(nd)harmonics the direction of current flow through dn and dp are opposite.However for odd harmonics, such as main signal current and 3^(rd)harmonics, direction of output currents through dn and dp are the same.

FIG. 2B is a second embodiment of a tuning block 200′ in accordance withthe present invention. The single ended tuning block 200′ includes oftwo inputs dn and dp, three outputs, s, gn and gp. The single endedtuning block 200′ has a supply (vdd), and ground (gnd). Input signal inthe form of current is inserted to nodes dn and dp with I_in_n andI_in_p respectively. Tuning block 200′ which can includes a combinationof all or few part of passive, inductors, capacitors, resistors andtransformers but not limited to any has a function of receiving I_in_nand I_in_p and then provide an output current, I_s at node S withfollowing condition: I_s>I_in_n +I_in_p. the output gp and gn arevoltages which will drive gn and gp nodes of the active device 100. Asshown in FIG. 3B, combining tuning block 200′ with active device 100,form a common-gate/common source amplifier action.

In addition, tuning block 200′ may only send gate information gn and gpand no information at S node. In this case, S node can be grounded orcoupled to any passive device such as resistor, capacitor, inductor,transformer or active device or all. Combination of tuning block 200′and active device 100, in this particular case form a common-sourceamplifier.

FIG. 3B is a block diagram of a combined common gate and common sourceamplifier in single ended form in accordance with the present invention.The common gate and common source amplifier comprises the active device100 coupled to the tuning block 200′. In this embodiment, current I_sfrom the tuning block 200′ is provided to the source connection, S ofthe active device 100. Due to common gate action of device for anycurrent entering node s, the current I_s will split and portion of itdirected to dn as output current I_out_n and the other portion directedto dp as output current I_out_p. The gates gn and gp of the activedevice 100 are coupled to bias lines as well as driven by output nodesof tuning block gn and gp. Bulk nodes, bn and by are also coupled totheir respective bias lines. Nodes gn and gp can further be connected totheir respective bias which is isolated from main signal.

FIG. 4A is a block diagram of a first embodiment of a differentialcommon gate amplifier 400 in accordance with the present invention. Theamplifier 400 comprises a differential tuning block 200 coupled to afirst and second active device 151. The differential tuning block 200comprises four inputs dn_in+, dp_in+ and dn_in−, dp_in−, and twooutput,s s+ and s−. A supply (vdd) and a ground (gnd) is provided. Inputsignals in the form of current are inserted to nodes dn_in+, dp_in+ anddn_in−, dp_in− as I_in_n+, I_in_p− and I_in_n− and I_in_p− respectively.Tuning block 200 which can include a combination of all or few part ofpassive, inductors, capacitors, resistors and transformers but notlimited to any has a function of receiving I_in_n+, I_in_p+ and I_in_n−,I_in_p− and process them as output currents I_s+ and I_s− at node S+ andS− respectively with following condition: I_s+>(I_in_n+)+(I_in_p+) andI_s−>(I_in_n−)+(I_in_p−)

In this embodiment, current I_s from the tuning block 200 is provided tothe source connection, S of the active device+ 151. Due to a common gateaction of device 151+, the current I_s will split and a portion of it isdirected to dn as output current I_out_n and the other portion directedto dp as output current I_out_p. The gates gn and gp of Active deviceare coupled to bias lines. (No signal is applied to gn and gp). Bulknodes, bn and by are also coupled to their respective bias lines.

Similarly, in this embodiment, current I_s from the tuning block 200 isprovided to the source connection, S of the active device 151−. Due to acommon gate action of device 15−, the current I_s will split and aportion of it is directed to dn as output current I_out_n and the otherportion directed to dp as output current I_out_p. The gates gn and gp ofActive device are coupled to bias lines. (No signal is applied to gn andgp). Bulk nodes, bn and by are also coupled to their respective biaslines.

Any number of capacitors or variable capacitors can be coupled between +and − nodes of inputs and of tuning block 200. As well any number ofcapacitors or variable capacitors can connect between + and − nodes ofinput, outputs, gates, bulks to input and outputs of active device+ 151and active device− 151. For example, cross capacitors or variablecapacitors can be coupled between dn+ and dn−; dp+ and dp−; dn− and dp+;dn+ and dp− and or any combination thereof. Also these capacitors orvariable capacitors can include series resistors or series inductance orparallel resistors or parallel inductors which do not affect or alterthe invention.

FIG. 4B is a block diagram of a second embodiment of a differentialcommon gate amplifier in accordance with the present invention. Theamplifier 400 comprises a differential tuning block 200 coupled to afirst and second active device 151. The differential tuning block 200comprises four inputs dn_in+, dp_in+ and dn_in−, dp_in−, and twooutput,s s+ and s−. A supply (vdd) and a ground (gnd) is provided. Inputsignals in the form of current are inserted to nodes dn_in+,dp_in+ anddn_in−, dp_in− as I_in_n+, I_in_p− and I_in_n− and I_in_p− respectively.A supply vdd in the left and gnd to the right. Tuning block 200 whichcan include a combination of all or few part of passive, inductors,capacitors, resistors and transformers but not limited to any has afunction of receiving I_in_n+, I_in_p+ and I_in_n− , I_in_p− and processthem as output currents I_s+ and I_s− at node S+ and S− respectiely withfollowing condition: I_s+>(I_in_n+)+(I_in_p+) andI_s−>(I_in_n−)+(I_in_p−).

In this embodiment, current I_s from the tuning block 200 is provided tothe source connection, S of the active device+ 151. Due to a common gateaction of device 151+, the current I_s will split and a portion of it isdirected to dn as output current I_out_n and the other portion directedto dp as output current I_out_p. The gates gn and gp of Active deviceare coupled to bias lines forming a virtual ground between + and − side(No signal differential signal is applied to gn and gp). Bulk nodes, bnand by are also coupled to their respective bias lines.

Similarly, in this embodiment, current I_s from the tuning block 200 isprovided to the source connection, S of the active device 151−. Due to acommon gate action of device 151−, the current I_s will split and aportion of it is directed to dn as output current I_out_n and the otherportion directed to dp as output current I_out_p The gate gn− is coupledto gate gn+ to form a virtual ground and they share a common biasvoltage, vbias_n. Similarlly, gp− and gp+ are coupled together to form avirtual ground and they share a common bias voltage, bias_p. Bulk nodes,bn− and bp− are also coupled to their respective bias lines.

Any number of capacitors or variable capacitors can be coupled between +and − nodes of inputs and outputs of tuning blocks 200. As well anynumber of capacitors or variable capacitors can connect between + and −nodes of input and outputs, gates, bulks and sources of active device+151 and active device− 151. For example, cross capacitors or variablecapacitors can be coupled between dn+ and dn−; dp+ and dp−; dn− and dp+;dn+ and dp− or any combination thereof. Also these capacitors orvariable capacitors can include series resistors or series inductance orparallel resistors or parallel inductors which do not affect or alterthe invention.

FIG. 4C is a block diagram of an embodiment of a differential combinedcommon gate and common source amplifier in accordance with the presentinvention. The amplifier 400 comprises a differential tuning block 200coupled to a first and second active device 151. The differential tuningblock 200 comprises four inputs n+, p+ and n−, d− and 6 outputs s+, s−,gn+, gn−, gp+, gp−. Also a supply vdd and gnd is provided for neededbiasing of any active device that is feeding nodes dn+, do−, dp+ anddp−.

Input signals are in the form of current and are provided to nodes n+,p+ and n−, p− as I_in_n+, I_in_p− and I_in_n− and I_in_p− respectively.Tuning block 200 which can include a combination of all or some ofpassive devices s such as inductors, capacitors, resistors andtransformers but not limited to any has a function of receiving I_in_n+,I_in_p+ and I_in_n−, I_in_p− and process them as output currents I_s+and I_s− at node S+ and S− respectively with following condition:I_s+>(I_in_n+)+ (I_in_p+) and I_s−>(I_in_n−)+(I_in_p−).

The other four output nodes of the tuning block 200 connect to positiveand negative n-type and p-type gates of active device+ 151 and activedevice− 151 respectively to form a differential common gate-commonsource amplifier.

Current I_s+ is provided to active device+ 151 source connection, S. Dueto common gate action of this device, the current I_s+ will split andportion of it is directed to dn+ as output current I_out_n+ and theother portion directed to dp+ as output current I_out_p+. The gates gn+and gp+ of active device+ 151 are coupled to bias lines. (No signal isapplied to gn+ and gp+). Bulk nodes, bn+ and bp+ are also coupled totheir respective bias lines.

Similarly, current I_s− is entering active device− 151 sourceconnection, S. Due to a common gate action of active device− 151, thecurrent I_s− will split and portion of it is directed to dn− as outputcurrent I_out_n− and the other portion directed to dp− as output currentI_out_p−.

Any number of capacitors or variable capacitors can connect between +and − nodes of inputs and outputs, gates and bulks and sources of tuningblock 200. As well any number of capacitors or variable capacitors canconnect between + and − nodes of input and outputs of active device+ 151and active device− 151. For example, cross capacitors or variablecapacitors can connect between dn+ and dn−; dp+ and dp−; dn− and dp+;dn+ and dp− and any combination thereof. Also these capacitors orvariable capacitors can include series resistors or series inductance orparallel resistors or parallel inductors, which do not affect or alterthe invention.

FIG. 4D is a block diagram of an embodiment of a single ended voltagecontrolled oscillator (VCO) 400 in accordance with the presentinvention. As is shown the active device 100 is coupled to the tuningblock 200 directly via the source and in a feedback relationship via thedrains.

FIG. 4E is a block diagram of an embodiment of a differential VCO 400′inaccordance with the present invention. As is shown, the active device151 is coupled to the tuning block 200 directly via the sources andgates and in a feedback relationship via the drains.

FIG. 4F is a block diagram of an embodiment of a cascaded VCO 400″ inaccordance with the present invention. FIG. 4F shows cascade of commonsource tuning and active devices. However a mix and match of common gateor common gate, common source or even common source can be implementedthat is in accordance with the present invention.

FIG. 4G is a block diagram of an embodiment of a differential VCO 410 inaccordance with the present invention. As is shown, the active device151 is coupled to the tuning block 200 directly via the sources and in afeedback relationship via the drains. Effective loop feedback has apositive sign to ensure oscillation.

FIG. 4H is a block diagram of an embodiment of a cascaded VCO 410′ inaccordance with the present invention. FIG. 4H shows cascade of commongate tuning and active devices. However a mix and match of common gateor common gate, common source or even common source can be implementedthat is in accordance with the present invention. The dotted lines meansmany of these blocks could be present.

FIG. 4I is a block diagram of an embodiment of a cascaded VCO 420 inaccordance with the present invention. FIG. 4i shows cascade of commongate tuning and active devices with common gate tuning and activedevices. The dotted line means there could be many combinations ofcommon gate active and tuning devices or common gate, common sourceactive and tuning devices.

FIG. 5 is a diagram of a two differential active devices coupled toinductive tuning blocks to form a VCO 500 in accordance with the presentinvention. FIG. 5 illustrates how to achieve positive feedback loop withgain greater than one and approaching gain of two using passiveinductance in combination with common gate amplifier. Clusters ofinductors, 200 are coupled to each other. This satisfies condition thatsource current is more than each drain current as specified with tuningblock functionality. Although not shown if FIG. 5, same polarity sourcescan connect together as well as same polarity dn or dp can connect toeach other without altering functionality. For example S+ of each activedevice, 151 can connect together. Or S− of each active device canconnect together.

FIG. 6 is a diagram of three differential active devices coupled toinductive tuning blocks to form a VCO 600 in accordance with the presentinvention. FIG. 6 illustrates how to achieve positive feedback loop withgain greater than one and approaching gain of three using passiveinductance in combination with common gate amplifier. Clusters ofinductors, 200 are coupled to each other. This satisfies condition thatsource current is more than each drain current as specified with tuningblock functionality. Although not shown if FIG. 6, same polarity sourcescan connect together as well as same polarity dn or dp can connect toeach other without altering functionality. For example S+ of each activedevice, 151 can connect together. Or S− of each active device canconnect together.

FIG. 7 is a diagram of four differential active devices coupled toinductive tuning blocks in accordance with the present invention. FIG. 7illustrates that the gain can be more than one and approaching gain offour by this positive feedback. All inductors grouped within dottedovals are coupled to each other. Same polarity source nodes of eachactive device can be connected together without altering the invention.Also same polarity dn and dp nodes of each active device can beconnected together without altering the invention.

FIG. 8 is a diagram showing where drain currents of two active devicesare added before the loop in a VCO 800 in accordance with the presentinvention. In so doing, the drain currents of the two devices are addedfirst and the drains are coupled to the source in a positive feedbackmanner. Similarly all or few similar polarity source nodes from eachdifferential active device to other differential active devices canconnect together without altering present invention.

FIG. 9 is a diagram showing where drain currents are added before theloop in a VCO 900 in accordance with the present invention. In so doing,the drain currents are added first and the three drains are coupled tothe source in a positive feedback manner. Similarly all or few similarpolarity source nodes from each differential active device to otherdifferential active devices can connect together without alteringpresent invention.

A system and method in accordance with the present invention provides aamplifier circuit that can be combined with a transformer to obtainincreased gain and positive feedback for voltage controlled oscillator(VCO) applications. The resulting device does not require a buffer ormemory and therefore is smaller in size and uses less power thanconventional VCOs.

Although the present invention has been described in accordance with theembodiments shown, one of ordinary skill in the art will readilyrecognize that there could be variations to the embodiments and thosevariations would be within the spirit and scope of the presentinvention. Accordingly, many modifications may be made by one ofordinary skill in the art without departing from the spirit and scope ofthe present invention.

What is claimed is:
 1. A voltage controlled oscillator (VCO) comprising:an active device, wherein the active device further includes an n-typetransistor having a drain, gate and bulk; a p-type transistor having adrain, gate and bulk; wherein the n-type transistor and the p-typetransistor share a common source; a first capacitor coupled between thegate of n-type transistor and the gate of p-type transistor; a secondcapacitor coupled between the drain of the n-type transistor and thedrain of p-type transistor; and a third capacitor coupled between thebulk of n-type transistor and the bulk of p-type transistor; a tuningblock coupled to the common source to form a common gate amplifier; andat least one tuning element coupled to the active device for changingthe overall capacitance of the VCO; wherein the VCO has a high breakdownvoltage, is memory less and traps even harmonic signals.
 2. The VCO ofclaim 1, wherein each of the first, second and third capacitorscomprises any of a variable capacitor, a capacitor coupled in serieswith a resistor, a capacitor coupled in parallel with a resistor; acapacitor coupled serially with an inductor, a capacitor coupled inparallel with an inductor.
 3. The VCO of claim 1, wherein the at leasttuning element includes any of inductors, capacitors, resistors andtransformers which comprises two inputs and one output.
 4. Adifferential voltage controlled oscillator (VCO) comprising: first andsecond active devices; wherein each of the first and second activedevices further includes an n type transistor having a drain, gate andbulk; a p-type transistor having a drain, gate and bulk; wherein then-type transistor and the p-type transistor share a common source; afirst capacitor coupled between the gate of n-type transistor and thegate of p-type transistor; a second capacitor coupled between the drainof the n-type transistor and the drain of p-type transistor; and a thirdcapacitor coupled between the bulk of n-type transistor and the bulk ofp-type transistor; a fourth capacitor coupled between the bulk of then-type transistor of first active device to shared source of secondactive device; a fifth capacitor coupled between bulk of p-typetransistor of first active device to shard source of second activedevice; a sixth capacitor coupled between the bulk n-type transistor ofsecond active device to shared source of first active device; a seventhcapacitor coupled between the bulk of p-type transistor of second activedevice to shared source of first active device; a tuning block coupledto the common source to form a common gate amplifier; at least one firsttuning device coupled between the drain of the n-type transistor of thefirst active device and the drain of the n-type transistor of the secondactive device; at least one second tuning device coupled between thesources of the n-type and p-type transistors of the first active deviceand the sources of the -type and p-type transistors of the second activedevice; and at least one third tuning device coupled between the drainof the p-type transistor of the first active device and the drain of thep-type transistor of the second first active device; wherein thedifferential VCO has a high breakdown voltage, is memory less and trapseven harmonic signals.
 5. The differential VCO of claim 4, wherein eachof the first, second and third capacitors comprises any of a variablecapacitor, a capacitor coupled in series with a resistor, a capacitorcoupled in parallel with a resistor; a capacitor coupled serially withan inductor, a capacitor coupled in parallel with an inductor.
 6. Thedifferential VCO of claim 4, wherein each of the first, second and thirdtuning elements includes any of inductors, capacitors, resistors andtransformers which comprises two inputs and one output.
 7. Thedifferential VCO of claim 4, wherein the first and second tuningelements are utilized for coarse tuning of the VCO and the second tuningelement is utilized for fine tuning of the VCO.